The theory tested in computer simulations could help explain why Jupiter’s interior defies logic
WRECKING BALLA planetary body about 10 times as massive as Earth may have smashed into Jupiter billions of years ago, creating the oddly diffuse core seen in the gas giant today.
Astrobiology Center, Japan
A planetary smashup billions of years ago may be to blame for Jupiter’s weirdly puffy core.
Recent measurements of Jupiter’s gravitational field indicate that, rather than a dense pit of rock and ice, Jupiter’s core is ahaze of heavy elementspossibly spanning half the planet’s radius (SN: 6/24/17, p. 14). That observation, made byNASA’s Juno spacecraftthat started orbiting Jupiter in 2016, flies in the face of current planet formation models (SN: 6/25/16, p. 16). Those models suggest that Jupiter would have formed from a dense kernel that accumulated a thick envelope of gas.
New computer simulations now show that a collision between Jupiter and another large planetary bodycould have shattered Jupiter’s original compact coreinto the scattered collection of heavy elements seen today. Understanding the origins of Jupiter’s internal structure may give insight into the processes that shape other gas giants in our solar system and around other stars, researchers report in the Aug. 15Nature.
“This impact may have happened when the solar system was very, very young, and in a chaotic phase when there were lots of objects roaming around,” says Andrea Isella, an astronomer at Rice University in Houston. As the biggest planetary body in its neighborhood, Jupiter was liable to gravitationally attract other objects wandering the solar system, he says.
Billions of years ago, Jupiter may have collided with a rogue planetary body equal to about 10 Earth masses (impact and its aftermath seen from left to right in this computer simulation). That impact could have fractured the gas giant’s original compact core and mixed the heavy elements there into its gaseous envelope to create the bloated, fuzzy core seen today.
Billions of years ago, Jupiter may have collided with a rogue planetary body equal to about 10 Earth masses (top row in this computer simulation). That impact could have fractured the gas giant’s original compact core and mixed the heavy elements there into its gaseous envelope to create the bloated, fuzzy core seen today (bottom right).
In the simulations, Isella and colleagues found that a planetary body of about 10 Earth masses could have broken apart and merged with Jupiter’s dense core, causing that jumble of material to mix into the planet’s inner gaseous envelope. Within hours, the merger would have transformed Jupiter’s original core, around only 15 percent the planet’s radius, into a dilute core that extended to nearly half of Jupiter’s radius. Further simulations confirmed that this diffuse core could have persisted for over 4 billion years to the present day.
The idea that a giant impact reshaped Jupiter’s internal structure is plausible, says Juno mission leader Scott Bolton of the Southwest Research Institute in San Antonio, who wasn’t involved in the study. But other scenarios — such as heavy elements mixing with gas during Jupiter’s formation, or an internal churning process dredging up core material — may also explain Jupiter’s diffuse core. Computer simulations of those competing scenarios may help scientists tease out which is most likely, Bolton says, noting that figuring out how Jupiter formed and evolved is very much “a work in progress.”